结核分枝杆菌
突变
利福平
抗药性
支原体
突变体
肺结核
生物
质粒
计算生物学
点突变
基因座(遗传学)
遗传学
抗生素
基因
医学
病理
作者
Zhao Hui,Jiachen Li,Siyuan Feng,Lin Xu,Bin Yan,Chengjuan Li,Meisong Li,Yaxuan Wang,Yaxin Li,Lujie Liang,Dianrong Zhou,Jia Wan,Wenli Wang,Guo‐Bao Tian,Bing Gu,Xi Huang
标识
DOI:10.1016/j.ijantimicag.2024.107158
摘要
Rifampicin is the most powerful first-line antibiotic for tuberculosis, which is caused by Mycobacterium tuberculosis. Although accumulating evidence from sequencing data of clinical M. tuberculosis isolates suggested that mutations in the rifampicin-resistance-determining region (RRDR) are strongly associated with rifampicin resistance, the comprehensive characterisation of RRDR polymorphisms that confer this resistance remains challenging. By incorporating I-SceI sites for I-SceI-based integrant removal and utilizing an L5 swap strategy, we efficiently replaced the integrated plasmid with alternative alleles, making mass allelic exchange feasible in mycobacteria. Using this method to establish a fitness-related gain-of function screen, we generated a mutant library that included all single-amino-acid mutations in the RRDR, and identified the important positions corresponding to some well-known rifampicin-resistance mutations (Q513, D516, S522, H525, R529, S531). We also detected a novel two-point mutation located in the RRDR confers a fitness advantage to M. smegmatis in the presence or absence of rifampicin. Our method provides a comprehensive insight into the growth phenotypes of RRDR mutants and should facilitate the development of anti-tuberculosis drugs.
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